Square-integrable function
2015-10-26 23:06
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In
mathematics, a square-integrable function, also called a
quadratically integrable function, is a
real- or
complex-valued
measurable function for which the
integral of the square of the
absolute value is finite. Thus, if
then ƒ is square integrable on the real line
. One may also speak of quadratic integrability
over bounded intervals such as [0, 1].[1]
An equivalent definition is to say that the square of the function itself (rather than of its absolute value) isLebesgue
integrable. For this to be true, the integrals of the positive and negative portions of the real part must both be finite, as well as those for the imaginary part.
Often the term is used not to refer to a specific function, but to a set of functions that are equalalmost everywhere.
product space with
inner product given by
where
f and g are square integrable functions,
f(x) is the
complex conjugate of f,
A is the set over which one integrates—in the first example (given in the introduction above),A is
; in the second,A is [0, 1].
Since |a|2 = a a, square integrability is the same as saying
It can be shown that square integrable functions form a
complete metric space under the metric induced by the inner product defined above. A complete metric space is also called aCauchy space, because
sequences in such metric spaces converge if and only if they areCauchy. A space which is complete under the metric induced by a norm is a
Banach space. Therefore the space of square integrable functions is a Banach space, under the metric induced by the norm, which in turn is induced by the inner product. As we have the additional property of the inner product, this is specifically aHilbert
space, because the space is complete under the metric induced by the inner product.
This inner product space is conventionally denoted by
and many times
abbreviated as
. Note that
denotes the set of square integrable functions, but no selection of metric, norm or inner product are specified by this notation. The set, together with the specific inner product
specify the inner product space.
The space of square integrable functions is the
Lp space in which p = 2.
Jump to:
navigation,
search
In
mathematics, a square-integrable function, also called a
quadratically integrable function, is a
real- or
complex-valued
measurable function for which the
integral of the square of the
absolute value is finite. Thus, if
then ƒ is square integrable on the real line
. One may also speak of quadratic integrability
over bounded intervals such as [0, 1].[1]
An equivalent definition is to say that the square of the function itself (rather than of its absolute value) isLebesgue
integrable. For this to be true, the integrals of the positive and negative portions of the real part must both be finite, as well as those for the imaginary part.
Often the term is used not to refer to a specific function, but to a set of functions that are equalalmost everywhere.
Properties
The square integrable functions (in the sense mentioned in which a "function" actually means a set of functions that are equal almost everywhere) form aninnerproduct space with
inner product given by
where
f and g are square integrable functions,
f(x) is the
complex conjugate of f,
A is the set over which one integrates—in the first example (given in the introduction above),A is
; in the second,A is [0, 1].
Since |a|2 = a a, square integrability is the same as saying
It can be shown that square integrable functions form a
complete metric space under the metric induced by the inner product defined above. A complete metric space is also called aCauchy space, because
sequences in such metric spaces converge if and only if they areCauchy. A space which is complete under the metric induced by a norm is a
Banach space. Therefore the space of square integrable functions is a Banach space, under the metric induced by the norm, which in turn is induced by the inner product. As we have the additional property of the inner product, this is specifically aHilbert
space, because the space is complete under the metric induced by the inner product.
This inner product space is conventionally denoted by
and many times
abbreviated as
. Note that
denotes the set of square integrable functions, but no selection of metric, norm or inner product are specified by this notation. The set, together with the specific inner product
specify the inner product space.
The space of square integrable functions is the
Lp space in which p = 2.